Measuring transfer functions of track structures in a test rig with laser Doppler vibrometer and accelerometers on a moving vehicle

•Continuously measure transfer functions of track structures on a moving vehicle.•Estimate wheel-rail force combining vehicle vibration and operational modal identification.•Use a laser Doppler vibrometer for non-contact measurement of track vibration.•Agreement with hammer tests at 200–800 Hz in a...

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Veröffentlicht in:Mechanical systems and signal processing 2024-05, Vol.214, p.111392, Article 111392
Hauptverfasser: Zeng, Yuanchen, Núñez, Alfredo, Li, Zili
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Sprache:eng
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Zusammenfassung:•Continuously measure transfer functions of track structures on a moving vehicle.•Estimate wheel-rail force combining vehicle vibration and operational modal identification.•Use a laser Doppler vibrometer for non-contact measurement of track vibration.•Agreement with hammer tests at 200–800 Hz in a vehicle-track test rig at the speed of 8–16 km/h.•Capture variation in track dynamic properties at different locations. A transfer function (TF) is an effective representation of the load-response relationship of railway track structures. To fill the gap in measuring track structure TFs over a wide frequency range from a moving vehicle, we develop a TF measurement system and the associated TF estimation methodology. Accelerometers are utilized to estimate the dynamic vehicle load to track structures, and a laser Doppler vibrometer (LDV) is used to scan track structures and measure their vibration response. First, operational modal analysis is applied to vehicle impact response over joints to identify its modal parameters, which support the estimation of dynamic wheel-rail forces from vehicle vibrations. This combination eliminates the need to pre-define the vehicle stiffness, vehicle damping, and vehicle body mass and enables the vehicle parameters to be updated under operational conditions. Meanwhile, a signal processing method is applied to LDV signals to reduce speckle noise and compensate for the effect of vehicle vibration. Then, a continuous track structure is segmented into distributed sections, and a TF is estimated for each track section using the estimated wheel-rail force as input and the extracted track vibration as output. We validate the methodology in a vehicle-track test rig on different track sections (with or without joints) and at different speeds (from 8 km/h to 16 km/h). The results are further compared with trackside measurements and hammer tests. We demonstrate that the track vibrations extracted from the LDV signals are consistent with those measured by trackside accelerometers. The shapes and resonance frequencies of the estimated TFs are in good agreement with those measured from the hammer tests in the frequency range of 200–800 Hz. The developed system captures differences in the TFs between different track sections, suggesting its potential to be used for structural health monitoring of railway tracks.
ISSN:0888-3270
1096-1216
DOI:10.1016/j.ymssp.2024.111392